Faster-Than-Real-Time Hardware Emulation of Transients and Dynamics of a Grid of Microgrids

IF 3.3 Q3 ENERGY & FUELS

IEEE Open Access Journal of Power and Energy Pub Date : 2023-01-01 DOI:10.1109/OAJPE.2022.3217601

Shiqi Cao;Ning Lin;Venkata Dinavahi

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Abstract

Enhanced environmental standards are leading to an increasing proportion of microgrids (MGs) being integrated with renewable energy resources in modern power systems, which brings new challenges to simulate such a complex system. In this work, comprehensive modeling of a grid of microgrids for faster-than-real-time (FTRT) emulation is proposed, which can be utilized in the energy control center for contingencies analysis and dynamic security assessment. Electromagnetic transient (EMT) modeling is applied to the microgrid in order to reflect the detailed device processes of the converter and renewable energy sources, while the AC grid utilizes the transient stability modeling to reduce the computational burden and obtain a high acceleration value over real-time execution. Consequently, a dynamic power injection interface is proposed for the coexistence of the two simulation types. The reconfigurability and parallelism of the field-programmable gate arrays (FPGAs) enable the whole system to be executed in FTRT mode with 51 times acceleration over real-time. Meanwhile, three case studies are emulated and the results are validated by the off-line simulation tool Matlab/Simulink®.

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微电网的瞬态和动态的超实时硬件仿真

随着环境标准的提高，现代电力系统中与可再生能源相结合的微电网比例越来越高，这给复杂系统的模拟带来了新的挑战。本文提出了基于超实时(FTRT)仿真的微电网综合建模方法，可用于能源控制中心的突发事件分析和动态安全评估。微电网采用电磁暂态(EMT)建模是为了反映变流器和可再生能源的详细器件过程，而交流电网采用暂态稳定建模是为了减少计算负担并在实时执行时获得较高的加速值。因此，提出了一种两种仿真类型共存的动态功率注入接口。现场可编程门阵列(fpga)的可重构性和并行性使整个系统能够在FTRT模式下以51倍的实时加速执行。同时，利用Matlab/Simulink®离线仿真工具对三个案例进行了仿真，并对仿真结果进行了验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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